Advancing Responsible Nanomaterials Use and Development …EPA’s definition of nanomaterials is...
Transcript of Advancing Responsible Nanomaterials Use and Development …EPA’s definition of nanomaterials is...
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Hazardous Waste and Toxics Reduction Program
March 2017 1 Publication No. 17-04-014
Responsible development of nanotechnology
Developing nanotechnology responsibly protects human health and the
environment while realizing social and economic benefits. Responsible
development addresses the design, use, and handling of nanomaterials
throughout the product life cycle including end-of-life considerations.
Responsible development of nanotechnology is an emerging chemical
policy for states and includes environmental, health, and safety
requirements, and best management practices.
Advancing green chemistry in Washington
In 2012, the Washington Department of Ecology (Ecology) in partnership
with the Department of Commerce created A Roadmap for Advancing
Green Chemistry in Washington State. A key feature of the roadmap
promotes safer alternatives and product innovation. Emerging
technologies and nanotechnology applications can play an important role
in the development of safer and improved options for products across
multiple sectors, including food, electronics, transportation, energy,
medicine, material storage, and environmental remediation. The
roadmap recognized “interdisciplinary cooperation is needed to achieve a
better understanding of the potential risks of nanotechnology and the
development of appropriate policies to address those concerns.”1
As product designers and consumers pursue better performance using
safer materials, a degree of uncertainty exists about engineered
nanomaterials. The scientific community, international governing bodies,
and the green chemistry roadmap point out that nanomaterials often
display unique properties distinct from the identical chemicals in bulk
form.
Advancing Responsible Nanomaterials
Use and Development in Washington State
Nanomaterial Defined
For this policy and to guide future
actions, nanomaterial is defined as:
A material with any external
dimension or internal structure of a
size ranging from approximately 1
to 100 nanometers. The particles
comprising a nanomaterial may be
bound, unbound, aggregated, or
agglomerated. Nanomaterials may
be naturally occurring or
engineered.
Examples of nanoscale internal
structures:
Tin oxide nanowires in flexible
macro-sized thin-sheet anodes
for advanced lithium ion
batteries.
Nano-sized diffraction gratings in
some high-efficiency solar cells.
Nanoscale pores in 3-D scaffolds
for bone and tissue regeneration.
This definition of nanomaterial is a
blend of definitions from the
International Organization for
Standardization (ISO), the European
Commission, and the State of
California.
https://fortress.wa.gov/ecy/publications/SummaryPages/1204009.htmlhttps://fortress.wa.gov/ecy/publications/SummaryPages/1204009.html
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An improved understanding of the transport, fate, bioavailability, and toxicity of nanomaterials will help determine
whether nanotechnologies are viable green chemistry options, but a risk framework is needed to evaluate them.
Guidance for risk evaluation of nanomaterials has not been adopted in Washington State or at the federal level.
Nor has Washington State or the federal government said how nanomaterials fit into broader chemical
management policies.
Toxicological tools that allow for rapid screening and alternative testing methods are in full development.
However, without a chemical policy inclusive of new materials and risk evaluation guidance, the potential
beneficial applications of nanomaterials cannot be fully integrated into the green chemistry roadmap.
After compiling a summary of ongoing actions within international governmental bodies, at the federal level, and at
Ecology, this paper explores options and provides recommendations to address how Washington State can
successfully integrate manufactured nanomaterials into the green chemistry roadmap.
Summary of manufactured nanomaterial policy initiatives
International
At the international level, the inclusion of nanomaterials in chemical management strategies is well underway. The
United Nations Environmental Program adopted the Strategic Approach to International Chemical Management
(SAICM) to move towards the production and use of chemicals, “in ways that minimize significant adverse impacts
on the environment and human health.”2 One of the five key emerging policy topics in the strategic approach is
nanotechnology. At its fourth international conference on chemical management held in the fall of 2015 in Geneva,
a broad resolution specific to nanotechnology was adopted that encourages stakeholders to “address the sound
management of manufactured nanomaterials.”
The Organization for Economic Cooperation and Development (OECD) is helping its member countries implement
the SAICM. In 2007, it established the OECD Working Party on Nanotechnology.3 Much of the OECD efforts have
focused on reviewing test methods for nanomaterial characterization and toxicological analyses.4 The European
Commission’s Health Program, along with eleven member states, funded Nanogentox to establish methods for
investigating the genotoxicity of nanomaterials. Various nations have nanomaterial registries, among them France,
Belgium, and Denmark. South Korea has developed an inventory of nano-products.
Federal
In the United States, the Environmental Protection Agency (EPA) proposed a draft rule on April 6, 2015, for
reporting and recordkeeping requirements for manufacturers or processors of certain nanomaterials. This action
is based on Section 8(a) of the Toxics Substances Control Act (TSCA). The comments EPA received indicate that the
EPA’s definition of nanomaterials is questioned. Some commenters argued that EPA does not have authority to
require nanomaterial reporting because they do not clearly fall under the definition of “chemical substances.” With
the ongoing TSCA reform, it is not clear how much more chemical management authority EPA will have or whether
states will be pre-empted from pursuing their own regulatory efforts.
In October 2016, the U.S. National Science and Technology Council updated the National Nanotechnology Initiative
(NNI) Strategic Plan.5 This document represents a consensus among the NNI agencies, including EPA, on the high-
level goals and priorities to pursue over the next three years or more. This plan provides a framework that the
states can use to address their own local needs.
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In January 2017, EPA issued an information-gathering rule to ensure a better understanding of nanoscale materials
in business. EPA issued a final regulation requiring one-time reporting and recordkeeping of existing exposure and
health and safety information on nanoscale chemical substances in commerce under TSCA, section 8(a).
This rule requires companies to notify EPA if they manufacture, import, or process certain chemical substances
already in commerce as nanoscale materials. The notification includes:
Specific chemical identity.
Production volume.
Methods of manufacture, processing, use, exposure, and release information.
Available health and safety data.
EPA will use this information to determine if further action under TSCA is needed, including additional information
collection. Persons who manufacture or process a reportable chemical substance during the three years prior to
the final effective date of this rule must report to EPA within a year of the rule’s publication.
Washington State
Ecology’s Hazardous Waste and Toxics Reduction (HWTR) Program has tracked scientific and policy developments
in nanotechnology since 2008. Ecology was represented at the international SAICM meeting in 2015 where
various nations presented their approaches to manufactured nanomaterial policy. Ecology is also:
Sponsoring training events and webinars.
Creating and managing the internal Emerging Technology SharePoint site.
Compiling nanomaterial safety protocols for Ecology field staff.
Interviewing academicians and other nanomaterial users and producers.
Joining and participating with the American National Standards Institute (ANSI) Technical Committee 229
on Nanotechnology (TC-229), through Northwest Green Chemistry.
Ecology and the University of Washington co-led a journal club on the “Applications of International Data
Standards Frameworks for Nanomaterials Risk Assessment.” The class reviewed major data standard frameworks
for nanomaterials, including that of ISO. Three case studies were selected:
1. Nano-silver in sippy cups and pacifiers.
2. Micro- and nano-titanium in food products.
3. Fullerenes in face creams.
Case studies, including the information currently available in the literature, were discussed in the context of the
ISO document 13121.
In 2016, Ecology purchased a Northwest Green Chemistry membership in the ISO ANSI TC 229 Technical Advisory
Group. The membership gives experts in the Pacific Northwest an opportunity to interact with and provide input
on international standards and reports. Collaborative work will help advance responsible nanotechnology and test
method development. Northwest Green Chemistry members are particularly interested in the following topics:
Environmental transport and fate of nanomaterials.
Ecotoxicity of nanomaterials.
Nanomaterial release into the environment during the product life cycle.
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The Washington Green Chemistry Roadmap points to the need to “participate in regional and national green
nanotechnology partnerships with industry, government, and NGOs to advance education and responsible
nanotechnology development in Washington State.” Participation in the ANSI/TAG 229 has produced useful
outcomes and should continue.
Another accomplishment from Ecology’s work with the ANSI TC-229 was introducing Dr. Robert Tanguay, a
leading researcher in the development of zebrafish toxicological assays, to a South Korean research group
interested in producing a standard method zebrafish assay. They are now jointly developing an international
standard for zebrafish screening assays that will prove useful in nano-toxicology worldwide.
Potential action plan for Washington State in fiscal year 2017-19
As Washington State progresses towards a comprehensive chemicals policy, Ecology should develop a set of
principles for managing chemicals responsibly including nanomaterials.
Ecology should integrate efforts of its Nanomaterials Work Group (NWG) into its Reducing Toxic Threats (RTT)
initiative. The RTT initiative is Ecology’s key effort in adopting a comprehensive chemicals policy. One of NWG’s
goals is to further integrate our work under the RTT banner. We recommend that the definition of “chemical
substance” be clearly and broadly defined to include emerging materials as well as existing materials. Washington
would also be well-served by collaborating with stakeholders to develop a set of principles for a comprehensive
chemical management strategy. This strategy would:
Support a framework for nanomaterial risk evaluation that promotes manufacturer responsibility to consider
life cycles that prevent negative impacts to human health and the environment.
Continue to track scientific and policy developments in nanotechnology and nano-toxicology.
Continue to monitor and participate with the ANSI TC-229 through Northwest Green Chemistry.
Budget and resource considerations over next biennium
Continue participation in ANSI TC-229 Health, Safety, and Environment Working Group. The estimated cost of
membership for two years through Northwest Green Chemistry is $3,025 annually. Ecology’s current
membership is good through 12/31/2016.
Support Ecology’s NWG by helping to coordinate meetings and events, literature reviews, SharePoint
organization, and similar tasks. The estimated cost for staff or intern at 0.05 FTE for 2 years is $11,000.
Allocate staff time (0.1 FTE) to represent or coordinate NWG meetings, mentor intern, and track issues of
importance. Ecology’s Jim Maroncelli of the Water Quality Program and Tom Boucher of the HWTR Program
coordinate this workgroup.
Other action items for consideration
Support a framework for nanomaterial risk evaluation promoting manufacturer responsibility in careful design
with life-cycle considerations to prevent negative impacts to human health and the environment. Apply the
relevant exposure assessment technologies being developed by the Harvard University School of Public Health.
The framework should address environmental health and safety issues for manufacturers and consumers, and
harmonize with the NNI Strategic Plan.
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Identify and attend relevant conferences or seminars on nanomaterials.
Host a roundtable discussion with stakeholders to help create a set of nanomaterial principles for a
comprehensive chemical management strategy in Washington. The estimated cost to retain a facilitator is
$10,000, based on a series of five meetings plus inter-meeting coordination time. Since the outcome will affect
most HWTR Program work, the cost may be shared with other program initiatives.
Consider product-testing opportunities of children’s and other consumer products. An estimated 0.2 FTE is
needed for Quality Assurance Project Plan development and determining budget options.
Water is emerging as an important focus both at the National Science Foundation (Food/Energy/Water nexus)
and in the new NNI Strategic Plan. It is also becoming increasingly important from a geopolitical standpoint.
Ecology’s expertise should play a key role in the production and protection of clean water using nanomaterials.
Develop external outreach materials, such as a website and focus sheets on issues and best practices.
Participate as a stakeholder where appropriate to align Ecology environmental health and safety goals with
Goal 4 of the U.S. NNI Strategic Plan and its sub-goals:
Goal 4: Support responsible development of nanotechnology.
4.1. Support the creation of a comprehensive knowledge base for evaluation of the potential risks and
benefits of nanotechnology to the environment and to human health and safety.
4.2. Create and employ means for timely dissemination, evaluation, and incorporation of relevant
environmental, health, and safety knowledge and best practices.
4.3. Develop the national capacity to identify, define, and responsibly address concepts and challenges
specific to the ethical, legal, and societal implications of nanotechnology.
4.4. Incorporate sustainability in the responsible development of nanotechnology.
Notes
1 Ecology. “A Roadmap for Advancing Green Chemistry in Washington State,” publication no. 12-04-009, Updated May 2013, Publication available at https://fortress.wa.gov/ecy/publications/documents/1204009.pdf.
2 Strategic Approach to International Chemicals Management. Visit www.saicm.org/About/SAICMOverview/tabid/5522/language/en-US/Default.aspx for an overview.
3 Organization for Economic Co-operation and Development. “Working Party on Nanotechnology (WPN): Vision Statement,” 1/26/2017. You'll find more information about nanotechnology at www.oecd.org/sti/nano/oecdworkingpartyonnanotechnologywpnvisionstatement.htm.
4 Organization for Economic Co-operation and Development. “Testing Programme of Manufactured Nanomaterials,” 1/26/2017. Visit their website at www.oecd.org/chemicalsafety/nanosafety/testing-programme-manufactured-nanomaterials.htm
5 National Science and Technology Council. “National Nanotechnology Initiative Strategic Plan,” October 31, 2016. Go to www.nano.gov/node/1676.
https://fortress.wa.gov/ecy/publications/documents/1204009.pdfhttp://www.saicm.org/About/SAICMOverview/tabid/5522/language/en-US/Default.aspxhttp://www.saicm.org/About/SAICMOverview/tabid/5522/language/en-US/Default.aspxhttp://www.oecd.org/sti/nano/oecdworkingpartyonnanotechnologywpnvisionstatement.htmhttp://www.oecd.org/sti/nano/oecdworkingpartyonnanotechnologywpnvisionstatement.htmhttp://www.oecd.org/chemicalsafety/nanosafety/testing-programme-manufactured-nanomaterials.htmhttp://www.oecd.org/chemicalsafety/nanosafety/testing-programme-manufactured-nanomaterials.htmhttp://www.nano.gov/node/1676http://www.nano.gov/node/1676